Oxidation Behavior of Zirconium Diboride Silicone Carbide Based Materials at Ultra-High Temperatures

Shugart, Kathleen

doi:10.18130/v3k51p

Cited by 2 publications

(1 citation statement)

References 43 publications

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“…Furthermore, it is fragile and does not have a good antioxidation property. A practical method for solving these problems, which limit the application of ZrB 2 , is composing it with other ceramics or metals [1][2][3][4][5]. The most important ZrB 2 -based composite is ZrB 2 -SiC, which is usually produced by various sintering procedures, i.e., pressure-less sintering, hot-pressing, microwave sintering and so on.…”

Section: Introductionmentioning

confidence: 99%

Role of Si3N4 on microstructure and hardness of hot-pressed ZrB2−SiC composites

et al. 2021

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The impact of Si3N4 content on the hardness and microstructural developments of ZrB2-SiC material has been investigated thoroughly in the present investigation. Having prepared the raw materials in a jar mill, the ZrB2-SiC samples containing various amounts of Si3N4 were hot-pressed at 1850 °C. Furthermore, XRD, FESEM, and HRTEM were utilized to evaluate the microstructure of samples. The formation of in-situ h-BN was proved by the mentioned methods. Also, it was shown that the Vickers hardness of ZrB2-SiC increases up to 20 GPa in presence of 4.5 wt% Si3N4 which is 3 GPa more than the sample without Si3N4. Results show that the positive effect of increased relative density on hardness is more than the negative effect of h-BN soft phase formation.

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Section: Introductionmentioning

confidence: 99%

Role of Si3N4 on microstructure and hardness of hot-pressed ZrB2−SiC composites

et al. 2021

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Analysis of Test Specimen Temperature Gradients Incurred in Resistive Heating System Oxidation Studies of Ultra-High Temperature Ceramics

Backman,

Graham,

Dion

et al. 2024

High Temperature Corrosion of mater.

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The need for advanced materials that can meet application requirements at ultra-high temperatures in oxidizing environments is an area of active research. One challenge facing the high temperature materials community is the ability to conduct controlled ultra-high temperature oxidation tests with minimal to no contamination or reaction with the chamber. A unique resistive heating system (RHS) capable of achieving ultra-high temperatures (> 1700 °C) to enable such experimentation is described. A concern of such a system is the potential presence of thermal gradients in directions not reflective of actual material applications, e.g., the hottest region being in the center of the sample. Experimental results from the oxidation of ZrB2 specimens at nominal temperatures of 1500°, 1700° and 1800 °C in low pO2 (0.1–1% O2 in Ar) environments are presented. Specimen thermal gradients generated during oxidation were evaluated using finite element analysis models. Thermal gradients on the order of the uncertainty in temperature measurements were calculated, confirming the RHS suitability for conducting ultra-high temperature oxidation exposures on ultra-high temperature ceramics.

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Oxidation Behavior of Zirconium Diboride Silicone Carbide Based Materials at Ultra-High Temperatures

Cited by 2 publications

References 43 publications

Role of Si3N4 on microstructure and hardness of hot-pressed ZrB2−SiC composites

Role of Si3N4 on microstructure and hardness of hot-pressed ZrB2−SiC composites

Analysis of Test Specimen Temperature Gradients Incurred in Resistive Heating System Oxidation Studies of Ultra-High Temperature Ceramics

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